High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR)
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Multi-dimensional Simulations of Emerging Flux Tubes
Yuhong Fan
National Center for Atmospheric Research
Jan. 16, 2002
Physical Questions Concerning Flux Emergence
• How does toroidal magnetic flux at the base of the solar convection zone destabilizes and form buoyant flux tubes?
• How do buoyant flux tubes rise in a reasonably cohesive manner through the solar convection zone to the surface?
• How do active region flux tubes emerge into the solar atmosphere?
Effects of Twist
• Maintaining cohesion of buoyantly rising flux tubes:– 2D simulations show a minimum twist needed (e.g. Longcope,
Fisher, & Arendt 1996; Moreno-Insertis & Emonet 1996; Emonet & Moreno-Insertis 1998; Fan, Zweibel, & Lantz 1998):
, or
– 3D arched tubes may require less twist (e.g. Abbett, Fisher, & Fan
2000; Fan 2001)
• Causes a tilt (writhe) of tube axis:– Kink unstable if twist is sufficiently high (e.g. Linton et al. 1996):
riseA VV
2/1)( aHq p
1aq
Where zrBBq /
Fan, Zweibel & Lantz (1998)
Abbett, Fisher, & Fan (2000)
• Rise of kink-unstable tube as a mechanism of delta-spot formation: (Linton et al. 1996, 1998, 1999; Fan et al. 1998, 1999):
8.11t 2.20t0t 4.40t 3.67t
E W
Left-handed twist: anti-clockwise rotation
right-handed twist: clockwise rotation
Destabilization of Toroidal Flux at the Base of SCZ
• Magnetic buoyancy instability of a horizontal magnetic field embedded in a vertically stratified plasma with constant gravity (Newcomb 1961; Hughes & Proctor 1988):– Unstable to general 3D modes if:
– Unstable to 2D interchange modes if:
xzBB ˆ)(
zgˆ
p
g
dz
d
2
4/2
2
Bp
g
dz
d
dz
ds
cdz
Bd
C
V
ps
a 1ln2
2
or
dz
ds
c
B
dz
d
C
V
ps
a 1ln
2
2
or
• Simulations of the magnetic buoyancy instability and the formation of buoyant flux tubes:
– Initial equilibrium magnetic layer that supports a top-heavy density stratification:
e.g. Cattaneo & Hughes (1988); Cattaneo, Chiueh, & Hughes (1990);
Matthews, Hughes, & Proctor (1995);
– Most unstable modes are the 2D interchange modes.
– 2D simulations show formation of strong vortices which rapidly destroys the coherence of the buoyant flux tubes and prevent the rise of magnetic flux.
– 3D simulations show that the flux tubes formed by the initial 2D interchange instability become unstable to 3D motion in the non-linear regime as a result of interaction between vortex tubes formation of arched tubes.
– 2D simulations of sheared magnetic layer show formation of twisted tubes which are able to rise cohesively.
Cattaneo & Hughes (1988)
Matthews, Hughes, & Proctor (1995)
– Simulations of 3D undulatory instability of a neutrally buoyant magnetic layer (Fan 2001):
Initial equilibrium is unstable to 3D undulatory modes, but is stable to 2D interchange modes:
Initial equilibrium profiles
xz
y
x
x
z
z
y
y
Intensification of Magnetic Field by Conversion of Potential Energy
(Rempel & Schuessler 2001)
• Weak flux tube rising through the superadiabatically stratified CZ can experience a sudden loss of pressure equilibrium (“explosion”) intensification of
submerged field at base of CZ: scHz ppl /exp
Flux Emergence into the Solar Atmosphere
• Magnetic buoyancy instability is a mechanism through which magnetic flux reaching the photosphere can expand dynamically into the stably stratified solar atmosphere:e.g. Shibata et al. 1989
• 2D and 3D simulations of flux emergence into the solar atmosphere:e.g. Shibata et al. 1989; Nozawa et al. 1992; Matsumoto et al. 1993; 1996;
Manchester 2001; Magara 2001; Fan 2001; Magara & Longcope 2001
2D simulations of the emergence of twisted flux tubes (Magara 2001):
2D simulations of the emergence of twisted flux tubes (Magara 2001)
The Role of Nonlinear Alfven Waves in Shear Formation During Solar Magnetic Flux Emergence (Manchester 2001)
xx BBF
Emergence of a Twisted -Tube (Fan 2001)
• Ideal MHD simulation using Zeus3D
• Adiabatic evolution, ideal gas with 3/5
Corona
Photosphere-Chromosphere
Top layer of CZ
Sigmoid Structure of an Emerging Flux Tube (Magara & Longcope 2001)
Flux emergence into the atmosphere driven by interior calculation of rising flux tube(Abbett & Fisher 2001)
Future Works
• Subsurface evolution:
– Spherical geometry
– Origin of twisted flux tubes
– Effects of Coriolis force
– Effects of Convection
• Flux Emergence into the solar atmosphere– Energy equation
Photosphere-Chormosphere: thermal relaxation
Heating mechanisms?
– Interaction with pre-existing coronal field
– Coupling to interior calculations of rising flux tubes
emgR